pmap.h source code [netbsd/sys/arch/i386/include/pmap.h]

1	/ $NetBSD: pmap.h,v 1.123 2019/03/09 09:09:56 maxv Exp $ /
2
3	/*
4	* Copyright (c) 1997 Charles D. Cranor and Washington University.
5	* All rights reserved.
6	*
7	* Redistribution and use in source and binary forms, with or without
8	* modification, are permitted provided that the following conditions
9	* are met:
10	* 1. Redistributions of source code must retain the above copyright
11	* notice, this list of conditions and the following disclaimer.
12	* 2. Redistributions in binary form must reproduce the above copyright
13	* notice, this list of conditions and the following disclaimer in the
14	* documentation and/or other materials provided with the distribution.
15	*
16	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
17	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
18	* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
19	* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
20	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
21	* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
22	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
23	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
24	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
25	* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
26	*/
27
28	/*
29	* Copyright (c) 2001 Wasabi Systems, Inc.
30	* All rights reserved.
31	*
32	* Written by Frank van der Linden for Wasabi Systems, Inc.
33	*
34	* Redistribution and use in source and binary forms, with or without
35	* modification, are permitted provided that the following conditions
36	* are met:
37	* 1. Redistributions of source code must retain the above copyright
38	* notice, this list of conditions and the following disclaimer.
39	* 2. Redistributions in binary form must reproduce the above copyright
40	* notice, this list of conditions and the following disclaimer in the
41	* documentation and/or other materials provided with the distribution.
42	* 3. All advertising materials mentioning features or use of this software
43	* must display the following acknowledgement:
44	* This product includes software developed for the NetBSD Project by
45	* Wasabi Systems, Inc.
46	* 4. The name of Wasabi Systems, Inc. may not be used to endorse
47	* or promote products derived from this software without specific prior
48	* written permission.
49	*
50	* THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND
51	* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
52	* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
53	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL WASABI SYSTEMS, INC
54	* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
55	* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
56	* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
57	* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
58	* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
59	* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
60	* POSSIBILITY OF SUCH DAMAGE.
61	*/
62
63	#ifndef _I386_PMAP_H_
64	#define _I386_PMAP_H_
65
66	#if defined(_KERNEL_OPT)
67	#include "opt_user_ldt.h"
68	#include "opt_xen.h"
69	#endif
70
71	#include <sys/atomic.h>
72
73	#include <i386/pte.h>
74	#include <machine/segments.h>
75	#if defined(_KERNEL)
76	#include <machine/cpufunc.h>
77	#endif
78
79	#include <uvm/uvm_object.h>
80	#ifdef XENPV
81	#include <xen/xenfunc.h>
82	#include <xen/xenpmap.h>
83	#endif /* XENPV */
84
85	/*
86	* see pte.h for a description of i386 MMU terminology and hardware
87	* interface.
88	*
89	* a pmap describes a processes' 4GB virtual address space. when PAE
90	* is not in use, this virtual address space can be broken up into 1024 4MB
91	* regions which are described by PDEs in the PDP. the PDEs are defined as
92	* follows:
93	*
94	* (ranges are inclusive -> exclusive, just like vm_map_entry start/end)
95	* (the following assumes that KERNBASE is 0xc0000000)
96	*
97	* PDE#s VA range usage
98	* 0->766 0x0 -> 0xbfc00000 user address space
99	* 767 0xbfc00000-> recursive mapping of PDP (used for
100	* 0xc0000000 linear mapping of PTPs)
101	* 768->1023 0xc0000000-> kernel address space (constant
102	* 0xffc00000 across all pmap's/processes)
103	* <end>
104	*
105	*
106	* note: a recursive PDP mapping provides a way to map all the PTEs for
107	* a 4GB address space into a linear chunk of virtual memory. in other
108	* words, the PTE for page 0 is the first int mapped into the 4MB recursive
109	* area. the PTE for page 1 is the second int. the very last int in the
110	* 4MB range is the PTE that maps VA 0xfffff000 (the last page in a 4GB
111	* address).
112	*
113	* all pmap's PD's must have the same values in slots 768->1023 so that
114	* the kernel is always mapped in every process. these values are loaded
115	* into the PD at pmap creation time.
116	*
117	* at any one time only one pmap can be active on a processor. this is
118	* the pmap whose PDP is pointed to by processor register %cr3. this pmap
119	* will have all its PTEs mapped into memory at the recursive mapping
120	* point (slot #767 as show above). when the pmap code wants to find the
121	* PTE for a virtual address, all it has to do is the following:
122	*
123	* address of PTE = (767 * 4MB) + (VA / PAGE_SIZE) * sizeof(pt_entry_t)
124	* = 0xbfc00000 + (VA / 4096) * 4
125	*
126	* what happens if the pmap layer is asked to perform an operation
127	* on a pmap that is not the one which is currently active? in that
128	* case we temporarily load this pmap, perform the operation, and mark
129	* the currently active one as pending lazy reload.
130	*
131	* the following figure shows the effects of the recursive PDP mapping:
132	*
133	* PDP (%cr3)
134	* +----+
135	* \| 0\| -> PTP#0 that maps VA 0x0 -> 0x400000
136	* \| \|
137	* \| \|
138	* \| 767\| -> points back to PDP (%cr3) mapping VA 0xbfc00000 -> 0xc0000000
139	* \| 768\| -> first kernel PTP (maps 0xc0000000 -> 0xc0400000)
140	* \| \|
141	* +----+
142	*
143	* note that the PDE#767 VA (0xbfc00000) is defined as "PTE_BASE"
144	*
145	* starting at VA 0xbfc00000 the current active PDP (%cr3) acts as a
146	* PTP:
147	*
148	* PTP#767 == PDP(%cr3) => maps VA 0xbfc00000 -> 0xc0000000
149	* +----+
150	* \| 0\| -> maps the contents of PTP#0 at VA 0xbfc00000->0xbfc01000
151	* \| \|
152	* \| \|
153	* \| 767\| -> maps contents of PTP#767 (the PDP) at VA 0xbfeff000
154	* \| 768\| -> maps contents of first kernel PTP
155	* \| \|
156	* \|1023\|
157	* +----+
158	*
159	* note that mapping of the PDP at PTP#767's VA (0xbfeff000) is
160	* defined as "PDP_BASE".... within that mapping there are two
161	* defines:
162	* "PDP_PDE" (0xbfeffbfc) is the VA of the PDE in the PDP
163	* which points back to itself.
164	*
165	* - PAE support -
166	* ---------------
167	*
168	* PAE adds another layer of indirection during address translation, breaking
169	* up the translation process in 3 different levels:
170	* - L3 page directory, containing 4 * 64-bits addresses (index determined by
171	* bits [31:30] from the virtual address). This breaks up the address space
172	* in 4 1GB regions.
173	* - the PD (L2), containing 512 64-bits addresses, breaking each L3 region
174	* in 512 * 2MB regions.
175	* - the PT (L1), also containing 512 64-bits addresses (at L1, the size of
176	* the pages is still 4K).
177	*
178	* The kernel virtual space is mapped by the last entry in the L3 page,
179	* the first 3 entries mapping the user VA space.
180	*
181	* Because the L3 has only 4 entries of 1GB each, we can't use recursive
182	* mappings at this level for PDP_PDE (this would eat up 2 of the 4GB
183	* virtual space). There are also restrictions imposed by Xen on the
184	* last entry of the L3 PD (reference count to this page cannot be
185	* bigger than 1), which makes it hard to use one L3 page per pmap to
186	* switch between pmaps using %cr3.
187	*
188	* As such, each CPU gets its own L3 page that is always loaded into its %cr3
189	* (ci_pae_l3_pd in the associated cpu_info struct). We claim that the VM has
190	* only a 2-level PTP (similar to the non-PAE case). L2 PD is now 4 contiguous
191	* pages long (corresponding to the 4 entries of the L3), and the different
192	* index/slots (like PDP_PDE) are adapted accordingly.
193	*
194	* Kernel space remains in L3[3], L3[0-2] maps the user VA space. Switching
195	* between pmaps consists in modifying the first 3 entries of the CPU's L3 page.
196	*
197	* PTE_BASE will need 4 entries in the L2 PD pages to map the L2 pages
198	* recursively.
199	*
200	* In addition, for Xen, we can't recursively map L3[3] (Xen wants the ref
201	* count on this page to be exactly one), so we use a shadow PD page for
202	* the last L2 PD. The shadow page could be static too, but to make pm_pdir[]
203	* contiguous we'll allocate/copy one page per pmap.
204	*/
205
206	/*
207	* Mask to get rid of the sign-extended part of addresses.
208	*/
209	#define VA_SIGN_MASK 0
210	#define VA_SIGN_NEG(va) ((va) \| VA_SIGN_MASK)
211	/*
212	* XXXfvdl this one's not right.
213	*/
214	#define VA_SIGN_POS(va) ((va) & ~VA_SIGN_MASK)
215
216	/*
217	* the following defines identify the slots used as described above.
218	*/
219	#ifdef PAE
220	#define L2_SLOT_PTE (KERNBASE/NBPD_L2-4) /* 1532: for recursive PDP map */
221	#define L2_SLOT_KERN (KERNBASE/NBPD_L2) /* 1536: start of kernel space */
222	#else /* PAE */
223	#define L2_SLOT_PTE (KERNBASE/NBPD_L2-1) /* 767: for recursive PDP map */
224	#define L2_SLOT_KERN (KERNBASE/NBPD_L2) /* 768: start of kernel space */
225	#endif /* PAE */
226
227	#define L2_SLOT_KERNBASE L2_SLOT_KERN
228
229	#define PDIR_SLOT_KERN L2_SLOT_KERN
230	#define PDIR_SLOT_PTE L2_SLOT_PTE
231
232	/*
233	* the following defines give the virtual addresses of various MMU
234	* data structures:
235	* PTE_BASE: the base VA of the linear PTE mappings
236	* PDP_BASE: the base VA of the recursive mapping of the PDP
237	* PDP_PDE: the VA of the PDE that points back to the PDP
238	*/
239
240	#define PTE_BASE ((pt_entry_t ) (PDIR_SLOT_PTE NBPD_L2))
241
242	#define L1_BASE PTE_BASE
243
244	#define L2_BASE ((pd_entry_t )((char )L1_BASE + L2_SLOT_PTE * NBPD_L1))
245
246	#define PDP_PDE (L2_BASE + PDIR_SLOT_PTE)
247
248	#define PDP_BASE L2_BASE
249
250	/ largest value (-1 for APTP space) /
251	#define NKL2_MAX_ENTRIES (NTOPLEVEL_PDES - (KERNBASE/NBPD_L2) - 1)
252	#define NKL1_MAX_ENTRIES (unsigned long)(NKL2_MAX_ENTRIES * NPDPG)
253
254	#define NKL2_KIMG_ENTRIES 0 /* XXX unused */
255
256	#define NKL2_START_ENTRIES 0 /* XXX computed on runtime */
257	#define NKL1_START_ENTRIES 0 /* XXX unused */
258
259	#ifndef XENPV
260	#define NTOPLEVEL_PDES (PAGE_SIZE * PDP_SIZE / (sizeof (pd_entry_t)))
261	#else /* !XENPV */
262	#ifdef PAE
263	#define NTOPLEVEL_PDES 1964 /* 1964-2047 reserved by Xen */
264	#else /* PAE */
265	#define NTOPLEVEL_PDES 1008 /* 1008-1023 reserved by Xen */
266	#endif /* PAE */
267	#endif /* !XENPV */
268	#define NPDPG (PAGE_SIZE / sizeof (pd_entry_t))
269
270	#define PTP_MASK_INITIALIZER { L1_MASK, L2_MASK }
271	#define PTP_FRAME_INITIALIZER { L1_FRAME, L2_FRAME }
272	#define PTP_SHIFT_INITIALIZER { L1_SHIFT, L2_SHIFT }
273	#define NKPTP_INITIALIZER { NKL1_START_ENTRIES, NKL2_START_ENTRIES }
274	#define NKPTPMAX_INITIALIZER { NKL1_MAX_ENTRIES, NKL2_MAX_ENTRIES }
275	#define NBPD_INITIALIZER { NBPD_L1, NBPD_L2 }
276	#define PDES_INITIALIZER { L2_BASE }
277
278	#define PTP_LEVELS 2
279
280	/*
281	* PTE_AVL usage: we make use of the ignored bits of the PTE
282	*/
283	#define PTE_WIRED PTE_AVL1 /* Wired Mapping */
284	#define PTE_PVLIST PTE_AVL2 /* Mapping has entry on pvlist */
285	#define PTE_X PTE_AVL3 /* Executable */
286
287	/ XXX To be deleted. /
288	#define PG_W PTE_WIRED
289	#define PG_PVLIST PTE_PVLIST
290	#define PG_X PTE_X
291
292	#include <x86/pmap.h>
293
294	#ifndef XENPV
295	#define pmap_pa2pte(a) (a)
296	#define pmap_pte2pa(a) ((a) & PTE_FRAME)
297	#define pmap_pte_set(p, n) do { *(p) = (n); } while (0)
298	#define pmap_pte_flush() /* nothing */
299
300	#ifdef PAE
301	#define pmap_pte_cas(p, o, n) atomic_cas_64((p), (o), (n))
302	#define pmap_pte_testset(p, n) \
303	atomic_swap_64((volatile uint64_t *)p, n)
304	#define pmap_pte_setbits(p, b) \
305	atomic_or_64((volatile uint64_t *)p, b)
306	#define pmap_pte_clearbits(p, b) \
307	atomic_and_64((volatile uint64_t *)p, ~(b))
308	#else /* PAE */
309	#define pmap_pte_cas(p, o, n) atomic_cas_32((p), (o), (n))
310	#define pmap_pte_testset(p, n) \
311	atomic_swap_ulong((volatile unsigned long *)p, n)
312	#define pmap_pte_setbits(p, b) \
313	atomic_or_ulong((volatile unsigned long *)p, b)
314	#define pmap_pte_clearbits(p, b) \
315	atomic_and_ulong((volatile unsigned long *)p, ~(b))
316	#endif /* PAE */
317
318	#else /* XENPV */
319	extern kmutex_t pte_lock;
320
321	static __inline pt_entry_t
322	pmap_pa2pte(paddr_t pa)
323	{
324	return (pt_entry_t)xpmap_ptom_masked(pa);
325	}
326
327	static __inline paddr_t
328	pmap_pte2pa(pt_entry_t pte)
329	{
330	return xpmap_mtop_masked(pte & PTE_FRAME);
331	}
332	static __inline void
333	pmap_pte_set(pt_entry_t *pte, pt_entry_t npte)
334	{
335	int s = splvm();
336	xpq_queue_pte_update(xpmap_ptetomach(pte), npte);
337	splx(s);
338	}
339
340	static __inline pt_entry_t
341	pmap_pte_cas(volatile pt_entry_t *ptep, pt_entry_t o, pt_entry_t n)
342	{
343	pt_entry_t opte;
344
345	mutex_enter(&pte_lock);
346	opte = *ptep;
347	if (opte == o) {
348	xpq_queue_pte_update(xpmap_ptetomach(__UNVOLATILE(ptep)), n);
349	xpq_flush_queue();
350	}
351	mutex_exit(&pte_lock);
352	return opte;
353	}
354
355	static __inline pt_entry_t
356	pmap_pte_testset(volatile pt_entry_t *pte, pt_entry_t npte)
357	{
358	pt_entry_t opte;
359
360	mutex_enter(&pte_lock);
361	opte = *pte;
362	xpq_queue_pte_update(xpmap_ptetomach(__UNVOLATILE(pte)),
363	npte);
364	xpq_flush_queue();
365	mutex_exit(&pte_lock);
366	return opte;
367	}
368
369	static __inline void
370	pmap_pte_setbits(volatile pt_entry_t *pte, pt_entry_t bits)
371	{
372	mutex_enter(&pte_lock);
373	xpq_queue_pte_update(xpmap_ptetomach(__UNVOLATILE(pte)), (*pte) \| bits);
374	xpq_flush_queue();
375	mutex_exit(&pte_lock);
376	}
377
378	static __inline void
379	pmap_pte_clearbits(volatile pt_entry_t *pte, pt_entry_t bits)
380	{
381	mutex_enter(&pte_lock);
382	xpq_queue_pte_update(xpmap_ptetomach(__UNVOLATILE(pte)),
383	(*pte) & ~bits);
384	xpq_flush_queue();
385	mutex_exit(&pte_lock);
386	}
387
388	static __inline void
389	pmap_pte_flush(void)
390	{
391	int s = splvm();
392	xpq_flush_queue();
393	splx(s);
394	}
395
396	#endif
397
398	struct vm_map;
399	struct trapframe;
400	struct pcb;
401
402	int pmap_exec_fixup(struct vm_map , struct* trapframe , struct* pcb *);
403
404	#include <x86/pmap_pv.h>
405
406	#define __HAVE_VM_PAGE_MD
407	#define VM_MDPAGE_INIT(pg) \
408	memset(&(pg)->mdpage, 0, sizeof((pg)->mdpage)); \
409	PMAP_PAGE_INIT(&(pg)->mdpage.mp_pp)
410
411	struct vm_page_md {
412	struct pmap_page mp_pp;
413	};
414
415	#endif /* _I386_PMAP_H_ */
416

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